Evolution of air interface towards 5G : radio access technology and performance analysis /

Over the past few decades, wireless access networks have evolved extensively to support the tremendous growth of consumer traffic. Evolution of Air Interface Towards 5G attempts to bring out some of the important developments that are contributing towards such growth.

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Das, Suvra Sekhar (Autor)
Otros Autores: Prasad, Ramjee
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Gitsrup, Denmark : River Publishers, [2018]
Colección:River Publishers series in communications.
Temas:
Wireless communication systems.
Mobile communication systems.
Transmission sans fil.
Radiocommunications mobiles.
TECHNOLOGY & ENGINEERING > Mechanical.
MEDICAL / Hospital Administration & Care
SCIENCE / Energy
Mobile communication systems
Wireless communication systems
Acceso en línea:Texto completo
Tabla de Contenidos:
  • Front Cover; Half Title; RIVER PUBLISHERS SERIES IN COMMUNICATIONS; Title Page; Copyright Page; Contents; Preface; Acknowledgements; List of Figures; List of Tables; List of Abbreviations; List of Important Symbols; Chapter 1
  • Introduction to 5G; 1.1 Introduction; 1.2 Development of LTE toward 5G; 1.3 Technologies Drivers for 5G; Chapter 2
  • Waveforms for Next-Generation Wireless Networks; 2.1 Introduction; 2.2 OFDM; 2.2.1 Channel; 2.2.2 Receiver; 2.3 5G Numerology; 2.3.1 Genesis; 2.3.2 Implementation; 2.4 Windowed OFDM; 2.4.1 Transmitter; 2.4.2 Receiver; 2.5 Filtered OFDM; 2.5.1 Transmitter.
  • 2.5.2 Receiver Processing2.6 GFDM; 2.6.1 Transmitter; 2.6.2 Receiver; 2.7 Precoded GFDM; 2.7.1 Block IDFT Precoded GFDM; 2.7.1.1 Joint processing; 2.7.1.2 BIDFT-N precoding; 2.7.1.3 Two-stage processing; 2.7.1.4 BIDFT-N precoding; 2.7.1.5 BIDFT-M precoding; 2.7.2 DFT Precoded GFDM; 2.7.3 SVD Precoded GFDM; 2.8 FBMC; 2.8.1 Cosine Modulated Tone; 2.8.2 Filter Characteristics; 2.8.3 Simplified Filter Characteristics; 2.8.4 MMSE Equalizer for FBMC; 2.9 UFMC; 2.9.1 Structure of UFMC Transceiver; 2.9.2 System Model for UFMC; 2.9.3 Output of the Receiver for the UFMC Transceiver Block Diagram.
  • 2.10 Performance ComparisonChapter 3
  • Non-orthogonal Multiple Access; 3.1 OFDM-based Non-orthogonal Multiple Access; 3.1.1 Algorithms for User Multiplexing and Power Allocation; 3.1.2 Performance Analysis; 3.2 Coordinated OFDM
  • NOMA; 3.2.1 System Model; 3.2.2 Solution Methodology and Proposed Algorithms; 3.3 User Selection and Optimal Power Allocation in NOMA; 3.3.1 System Model; 3.3.2 Performance Analysis; Chapter 4
  • Millimeter-Wave Communication; 4.1 Millimeter-Wave Channel Modeling; 4.1.1 Radio and Propagation Channel Models; 4.1.2 Large-Scale Channel Model.
  • 4.1.3 MIMO Spatial Channel Model4.2 Millimeter-Wave Communications; 4.2.1 Challenges; 4.2.2 State-of-the-Art Technology and Standards; 4.2.3 Millimeter-Wave Applications for 5G; 4.3 Rician K-Factor for Indoor mmWave Channels; 4.3.1 Rician K-Factor Calculation for the Multicluster With Directivity Saleh-Valenzuela Model; 4.3.2 Rician K-Factor Calculation for the Modified SV Modelfor mmW; 4.3.3 Modified SV Model for mmW; 4.3.4 IEEE 802.11ad Model; 4.3.5 Variation of K-Factor With Respect to Link Orientations; 4.3.6 Impact of Rician K-Factor on System BER.
  • 4.4 mmWave MIMO in Channels with Realistic Spatial Correlation4.4.1 Analytical Modeling of the Composite PAS; 4.4.2 Performance Analysis; 4.4.3 Hybrid Beamforming; Chapter 5
  • Heterogeneous Networks; 5.1 Femtocell-/Small Cell-based Heterogeneous Networks; 5.1.1 Femtocells/Small cells; 5.1.2 Deployment Modes; 5.1.3 Access Mechanisms; 5.1.4 Issues Related to Femtocell/Small cell Deployment; 5.1.5 Control Mechanisms for Femto Base Stations; 5.1.6 Area Spectral Efficiency Analysis of Co-Channel Heterogeneous network; 5.1.6.1 Spectral efficiency of a macrocell network.

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